C-Terminal Retroviral-Type Zinc Finger Domain from the HIV- 1

Protein Is Structurally Similar to the N-Terminal Zinc Finger Domain? Terri L. South,* Paul R. Blake,* Dennis R. Hare,l and Michael F. Summers***. Dep...
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6342

Biochemistry 1991, 30, 6342-6349

C-Terminal Retroviral-Type Zinc Finger Domain from the HIV- 1 Nucleocapsid Protein Is Structurally Similar to the N-Terminal Zinc Finger Domain? Terri L. South,* Paul R. Blake,* Dennis R. Hare,l and Michael F. Summers*** Department of Chemistry and Biochemistry, University of Maryland, Baltimore County, Baltimore, Maryland 21 228, and Hare Research, Incorporated, 14810 21 6th Avenue North East, Woodinville, Washington 98072 Received February 4, 1991; Revised Manuscript Received March 15, 1991

ABSTRACT: Twedimensional N M R spectroscopic and computational methods were employed for the structure determination of an 18-residue peptide with the amino acid sequence of the C-terminal retroviral-type (r-t.) zinc finger domain from the nucleocapsid protein (NCP) of HIV-1 [Zn(HIVl-F2)]. Unlike results obtained for the first retroviral-type zinc finger peptide, Zn(HIV1-Fl), [Summers et al. (1990) Biochemistry 29, 3291, broad signals indicative of conformational lability were observed in the 'H N M R spectrum of Zn(HIVl-F2) a t 25 O C . The N M R signals narrowed upon cooling to -2 OC, enabling complete ' H N M R signal assignment via standard two-dimensional (2D) N M R methods. Distance restraints obtained from qualitative analysis of 2D nuclear Overhauser effect (NOESY) data were used to generate 30 distance geometry (DG) structures with penalties (penalty = sum of the squared differences between interatomic distances defined in the restraints file and in the DG structures) in the range 0.02-0.03 A*. All structures were qualitatively consistent with the experimental NOESY spectrum based on comparisons with 2D NOESY back-calculated spectra. Superposition of the backbone atoms (C, C a , N ) for residues C ( 1)-C( 14) gave pairwise RMSD values in the range 0.16-0.75 A. The folding of Zn(HIVl-F2) is very similar to that observed for Zn(HIV1-Fl). Small differences observed between the two finger domains are localized to residues between His(9) and Cys(l4), with residues M(ll)-C(14) forming a 310 helical corner. Superposition of Zn(HIVl-F2) structures onto Zn(HIV1-F1) structures gave pairwise RMSD values in the ranges 0.4-0.7 A [backbone atoms of residues C( 1)-H(9) superpositioned] and 0.7-1.2 A [backbone atoms of residues C( 1)-C(14) superpositioned]. These results indicate that the r.t. zinc finger sequences observed in retroviral NCPs, simple plant virus coat proteins, and in a human single-stranded nucleic acid binding protein share a common structural motif.

w t hout exception, retroviral nucleocapsid proteins (NCPs) contain one or two copies of a conserved "retroviral-type" (r.t,) zinc finger sequence, Cys-X2-Cys-X4-His-X4-Cys(Henderson et al., 1981; Copeland et al., 1984), which has been proposed to function physiologically as a zinc-binding domain (Berg, 1986). This motif is not limited to retroviral proteins and has been observed in proteins from yeast transposable element copia, cauliflower mosaic virus, and more recently from humans in a cellular nucleic acid binding protein (CNBP) that contains seven sequential copies of the motif (South & Summers, 1990; Berg, 1990). A common feature of proteins containing the r.t. zinc finger sequence is that they appear to be involved at some stage in sequence-specific single-stranded nucleic acid interactions. Thus the conserved sequence may represent a generic zinc finger motif for single-stranded nucleic acid binding, analogous to the classical-type zinc finger motif found widely in duplex-DNA-binding proteins (Summers, 1991). Studies from several laboratories involving synthetic r.t. zinc finger peptides and synthetic proteins have shown that these sequences are capable of binding zinc stoichiometrically and with high affinity (South et al., 1989, 1990a; Green & Berg, 1989; Roberts et al., 1989; Summers et al., 1990). Low zinc This work was supported by ACS Institutional Research Grant IN-l47F, administered by the MD Cancer Program/University of Maryland (M.F.S.), and by NIH Grant GM42561 (M.F.S.). * Author to whom correspondence should be addressed. *Universityof Maryland, Baltimore County. f Hare Research, Inc.

0006-2960/91/0430-6342$02.50/0

dissociation constants ( 10-10-10-12M) measured for synthetic r.t. zinc finger peptides and a synthetic protein indicate that, under normal cellular conditions, these domains should be fully populated with zinc (Green & Berg, 1990). Indeed, HIV-1 particles appear to contain sufficient quantities of zinc to populate the NCP r.t. zinc finger domains (South et al., 1990b). Detailed NMR-based structural studies of a peptide with sequence of the first HIV-1 NCP zinc finger domain, Zn(H1V 1-Fl), revealed a novel structural motif containing extensive internal hydrogen bonding (Summers et al., 1990). The folding of residues C(l)-K(6) [a numbering scheme is used where the first Cys of the domain is labled C(l)] is virtually identical with the folding exhibited by related ironbinding residues of rubredoxin (Adman et al., 1975). More recently, we established that the intact HIV-1 nucleocapsid protein, isolated from virus particles and reconstituted with zinc, gives NMR spectra with features that are remarkably similar to features observed in the NMR spectra of Zn(HIV1-Fl) (South et al., 1990b) and with a peptide containing the sequence of the C-terminal r.t. zinc finger domain, Zn(HIV1-F2) [the amino acid sequence of Zn(HIV 1-F2) is K-G-C-W-K-C-G-K-E-G-H-Q-M-K-D-C-T-E]. To determine if the C-terminal r.t. zinc finger domain adopts folding similar to that of the N-terminal domain, 2D NMR and structural studies have been carried out on the synthetic metallopeptide Zn(HIVl-F2). This represents the second structural study of an r.t. zinc finger peptide and is an important step toward the NMR signal assignment and structure determination of the intact HIV-1 nucleocapsid protein. 0 1991 American Chemical Society

Biochemistry, Vol. 30, No. 25, 1991 6343

Zinc Finger in HIV Nucleocapsid EXPERIMENTAL PROCEDURES Computations. NMR data processing and structure calculations were carried out with Silicon Graphics 4D-20 and 4D-220 computers. NMR data were transferred via ethernet and converted to "readable" files with an in-house program (GENET).NMR data processing and analysis, distance geometry calculations, and NOESY back-calculations were performed with FTNMR, DSPACE, and BKCALC software packages (Hare Research, Inc). N M R Spectroscopy. NMR data were collected with a GE GN500 (500.1 1-MHz, 'H) N M R spectrometer. Sample conditions were as follows: 10 mg (9.5 mM) of Zn(HIVl-F2) (Peptide Technologies Inc., Washington, D. C.) in D 2 0 (99.9%, MSD) or 90% H20/10% D 2 0 solutions, pH 7.0, -2 OC. 'H NMR chemical shifts were referenced to internal H 2 0 (5.03 ppm at -2 "C). 2D NMR data were collected without sample spinning. All homonuclear 2D NMR data were processed with zero filling to a final spectrum size of 2048 X 2048 noncomplex data points. Pulse sequences and parameters used to collect and process the 2D NMR data are described below. 2D NOESY data (T, = 50,150, and 300 ms) for the sample containing 90% H 2 0 / 10% D 2 0 were obtained with a recycle delay of 2.5 s and were processed with 6-Hz exponential line broadening in t 2 and 90O-shifted squared sine bell filtering in t l , with third-order polynomial baseline correction in the FI domain subsequent to the final Fourier transform. Solvent suppression was achieved either with a 1-1-echo read pulse sequence (Sklenar & Bax, 1987; read delay periods and T2 of 90 and 210 ps, respectively) or with a combination of DANTE presaturation (+90° phase shifted relative to the preparation pulse) (Morris & Freeman, 1978; Zuiderweg et al., 1986), followed by a SCUBA pulse train (Brown et al., 1988) for partial recovery of saturated a-protons. Other parameters were as follows: 2 X 256 X 2048 data matrix sizes; 64 scans per tl increment. For D 2 0 solutions: 2 X 256 X 2048 raw data matrix sizes; 48 scans per t l increment. Phase-sensitive HOHAHA data (Davis & Bax, 1985) were obtained for aqueous samples with a 1-i-echo read pulse (Bax et al., 1987) with read delay periods of 90 ( 7 ' ) and 210 ps ( T ~ ) . Other parameters were as follows: 2 X 256 X 4096 data matrix size [two separate sets of States-Haberkorn-type data (States et al., 1982), with 256 data points in t l and 4096 data points in t 2 ] ;64 scans per t l increment; recycle delay = 2 s; MLEV- 17 mixing period = 45 ms, preceded and followed by 2.0-ms trim pulses; 8.1 kHz spin-lock field strength; 90' squared sine bell filtering in the t 2 and t l dimensions. 2QF phase-sensitive COSY (Pinantini et al., 1982) data were obtained for the Zn(HIVl-F2) sample (DzO solution) with solvent preirradiation to eliminate the residual HDO signal. The 2D data matrix (2 X 512 X 2048 complex points) was processed with 4-Hz exponential line broadening in the t2 dimension and 8-Hz exponential plus trapezoidal filtering in the t l dimension.

RESULTS Effect of Temperature on ID Spectra. Broad signals observed in the 1D 'H NMR spectrum obtained for Zn(HIV1F2) at temperatures above approximately 10 OC indicate that the molecule is conformationally labile. Variable temperature 'H NMR data obtained for Zn(HIV1-F2) are shown in Figure I . At 40 OC all aromatic protons gave rise to broad 'H NMR signals. When the temperature was lowered to -2 OC, the aromatic proton NMR signals narrowed considerably, and several of the Trp aromatic proton signals exhibited expected

8.0

7.4

PPm

6.8

1: Downfield region of the 'H NMR spectra obtained for Zn(HIVl-F2) over the temperature range -2-40 O C . The signal narrowing at lower temperatures reflects reduced conformational lability. FIGURE

8

lrpNH I

1014

916

818

810

7.2

PPm

Downfield region of the 2D NOESY spectrum obtained for Zn(HIVl-F2) (9.5 mM; 90% H20/10%D 2 0 pH 7) showing connectivities involving amide and aromatic protons. The spectrum is not symmetric with respect to the diagonal due to the nonlinear I-T-echo excitation pulse employed. FIGURE 2:

splitting due to scalar coupling (Figure 1). These data reflect a decrease in conformational lability at lower temperatures. NMR Signal Assignments. All 2D NMR data for signal assignment and structure determination were obtained for 9.5 mM Zn(HIVl-F2) samples at -2 OC. 'H NMR signal assignments were made by determining scalar connectivities within amino acid residues from COSY and HOHAHA spectra and then correlating the signals of adjacent residues on the basis of dipolar connectivities obtained from 2D NOESY data (Table I). This approach has been described in detail (Wuthrich, 1986). Three stretches of NH-NH connectivities were observed: W(2)-K(6), M( 1l)-C( 14), and T(+l)-E(+2) (Figure 2). The most intense NH-NH connectivities were observed for the K(3)-C(4), C(4)-G(5), and D( 13)-C( 14) proton pairs. Dipolar connectivities from amide protons to a- and side-chain protons were also used for sequential signal assignments, and the "fingerprint" region of the NOESY spectrum that contains these connectivities is

South et al.

6344 Biochemistry, Vol. 30, No. 25, 1991

Table I: 'H NMR Chemical Shift Assignments for Zn(HIVl-F2)" residue

NH b

CaH 3.93

8.74 8.19

3.74 3.37 3.96

8.79

4.36

9.39

4.16

2.26

8.50

4.89

3.17 2.49

8.46

4.07 3.80 4.34

8.58

4.16

8.75

4.36 3.66 4.78

8.16

7.16

CBH 1.84

2.84 2.00 3.46 3.35

1.85 1.79 1.98d 3.16

4.63

9.03

4.76

1.89 2.03d 2.16d

8.77

4.12

1.71d

4.88

7.75

3.65

H2,7.31 H4,7.57 H5,7.10 H6,7.19 H7,7.46 NH, 10.16 yCHZ,1.64' BCH2,1.25' tCH2,2.88

I 9.'6

yCH2,1.39 6CH2,I .56 cCH2,2.94 yCH2, 2.26d 2.14d H2 7.44 H46.80 yCH2, 2.03d ~CH,,2.49~ CH3,2.10 yCH2, 1 .8Svd 6CH2, 1.2lCd tCH2.2.87

2.94 2.51 3.28 2.85 4.43 1.82

CH3,1.06 yCH2,2.34d 2.16d "Chemical shift in ppm relative to internal H 2 0 (5.03 ppm) at -2 OC. bSignal for terminal NH3+ not observed. Coverlap precluded unambiguous differentiation of the y and 6 methylene proton signals for a given amino acid residue. dOverlap precluded unambiguous differentiation of the fl and y methylene proton signals for a given amino acid residue. 8.44 8.67

4.43 4.04

shown in Figure 3. Sequential NOESY connectivity data and relative amide proton labilities are summarized in Figure 4. Structure Determination Modification of our Original Approach. In our earlier studies of Zn(HIV1-Fl), 2D NOESY back calculations were used extensively as part of the structure refinement approach (Summers et al., 1990). In that approach, randomly embedded initial atom positions were treated with minimal (low-velocity) simulated annealing, affording DG structures with modest penalty values (ca. 3-5 A*). These DG structures were then subjected to conjugate gradient minimization (CGM), affording new structures with penalties in the range of ca. 0.5-2 A*. When additional CGM was unable to further reduce the penalty for a particular structure, 2D NOESY back calculations were performed, and new distance restraints dictated by discrepancies between the experimental and back-calculated spectra were added to the experimental restraints list. Freshly embedded DG structures minimized with the modified restraints list generally exhibited penalty values lower than those of the previously refined structures, and the new DG structures

-

3

8.8

I 7.'2

8.0 PPm

FIGURE 3: "Fingerprint" region of the 2D NOESY spectrum obtained for Zn(HIV1-F2) showing connectivities from amide and aromatic protons to CY- and side-chain protons. Zn(HIVl-FZ) NH

9.03

7.96

others yCH2,1.42' 6CH2,1.64C tCH2,2.89

d~~

d d

dm

Zn(HIV1-F1) NH

d~~ %N

dm

K G C W K C G K E G H 0M K D C T E ~ .O . .O . ... a lD O .

- I

-I

- - L I

- L I

I t -

V K C FNC G K EG H I A R NC RA

eo0

0.aD....rD00~000

'I

m I

I

a

I-

a

FIGURE4: Sequential NOESY connectivities used in the assignment of the 'H NMR spectrum of Zn(HIV1-F2) (T = -2 "C). For comparison, relevant results for Zn(HIV1-Fl) ( T = 30 "C)are included. Filled, shaded, and open circles reflect estimated low-, moderate-, and high-sensitivity, respectively, of the amide proton signal intensity to solvent preirradiation. d", daN, and dsN represent NOESY connectivities from backbone amide protons to neighboring amide protons, a-protons,and @-protons,respectively. The relative intensities of the NOES,classified as strong, medium, and weak, are indicated by the thickness of the horizontal lines. The star (*) represents potential connectivities that could not be unambiguously assigned due to signal overlap.

generally gave back-calculated NOESY spectra that were more consistent with experimental data. This cycle of (1) random embedding, followed by (2) minimal simulated annealing/CGM, (3) back calculation, and (4) restraints modification was repeated iteratively until structures consistent with the experimental data could be obtained. Thus, in our earlier approach, addition of restraints based on iterative 2D NOESY back calculations led to modifications of the +,@ penalty surface function, and enough restraints were eventually added to allow generation of low-penalty structures with only minimal (low-velocity) simulated annealing and conjugate gradient minimization steps. Final DG structures generated in this manner exhibited penalties of less than 0.21 AZ.Most important, low penalties (C0.21 Az)were also obtained when these final structures were reanalyzed with the initial set of experimental restraints (Le., restraints generated prior to any back calculating). Clearly, our earlier application of minimal simulated annealing and GCM was insufficient for adequate sampling of conformational space.

Zinc Finger in HIV Nucleocapsid

Biochemistry, Vol. 30, No. 25, 1991 6345

Table 11: Covalent and Experimental Restraints Used To Generate Zn(HIV 1-F2) Structures" Covalent Restraints Atoms with Assigned Prochiral Protons ~ 3 1 ca[71 cb[16] a61 cb[l I] Restraints to Zinc cb[3] 3.3581 sg[3] 2.3 ne2[11] 2.0 cb[6] 3.3581 sg[6] 2.3 n d l [ l l ] 4.13 cb[16] 3.3581 sgl161 2.3 call11 4.13 Experimental Restraints Based on Direct N O E Cross Peaks Alpha to Alpha ha[3] ha[12] 2.0 3.0 has[2] ha[9] 2.0 3.0 har[2] ha[9] 2.0 3.0

--

Amide to Amide hn[4] hn[5] 2.0 3.0 hn[13] hn[5] hn[6] 2.0 2.5 hn[14] hn[6] hn[7] 2.0 2.5 hn[15] hn[7] hn[8] 2.0 2.5 hn[17] hn[lO] h n [ l l ] 2.0 2.5 Amide to Alpha hn[2] har[2] 2.0 4.0 hn[ll] hn[2] has[2] 2.0 4.0 ha[12] hn[3] har[2] 2.0 3.0 hn[13] hn[3] has[2] 2.0 3.0 hn[13] hn[3] ha[3] 2.0 3.0 hn[14] hn[4] ha[3] 2.0 2.5 hn[14] hn[4] ha[4] 2.0 3.0 hn[15] hn[5] ha[4] 2.0 4.0 hn[15] hn[6] ha[6] 2.0 4.5 hn[16] hn[7] har[7] 2.0 2.5 hn[16] hn[8] has[7] 2.0 3.0 hn[17] hn[8] ha[8] 2.0 3.0 hn[17] hn[9] ha[8] 2.0 2.5 hn[18] hn[9] ha[9] 2.0 4.0 hn[18] hn[18] hn[ IO] ha[9] 2.0 4.0

hn[14] hn[15] hn[16] hn[18]

2.0 2.0 2.0 2.0

Hd2(9)

1

3.0 3.0 2.5 3.0 D

ha[9] 2.0 4.0 ha[12] 2.0 3.0 ha[3] 2.0 4.0 ha[13] 2.0 3.0 ha[13] 2.0 4.0 ha[14] 2.0 3.0 ha[14] 2.0 4.0 ha[15] 2.0 4.0 ha[13] 2.0 4.0 ha[16] 2.0 3.0 ha[16] 2.0 3.0 ha[17] 2.0 3.0 ha[16] 2.0 3.0 ha[17] 2.0 3.0 ha[18] 2.0 3.0

Amide to Beta hn[3] hbr[3] 2.0 3.0 hn[12] hbr[l2] 2.0 3.0 hn[3] hbs[3] 2.0 3.0 hn[12] hbr[l5] 2.0 4.0 hn[4] hbr[4] 2.0 3.0 hn[13] hbs[l3] 2.0 3.0 hn[4] hbs[4] 2.0 4.0 hn[14] hbs[l3] 2.0 3.0 hn[6] hbr[3] 2.0 4.0 hn[15] hbs[ll] 2.0 4.0 hn[6] hbr[6] 2.0 3.0 hn[15] hbs[l5] 2.0 3.0 hn[7] hbr[3] 2.0 3.0 hn[16] hbs[l6] 2.0 2.5 hn[8] hbr[3] 2.0 3.0 hn[16] hbr[l6] 2.0 3.0 hn[ 121 hbs[ 1 I] 2.0 3.0 alpha to side chain ha[3] hbs[3] 2.0 3.0 ha[13] hbr[l3] 2.0 4.0 ha[4] hbr[4] 2.0 3.0 ha[13] hbs[l3] 2.0 3.0 ha[4] hbs[4] 2.0 3.0 ha[13] hbs[l6] 2.0 3.0 ha[6] hbs[6] 2.0 2.5 ha[15] hbs[l5] 2.0 3.0 ha[6] hbr[6] 2.0 2.5 ha[16] hbr[l6] 2.0 4.0 h a [ l l ] hbr[ll] 2.0 3.0 ha[16] hbs[l6] 2.0 3.0 Histidine Aromatics hd2[11] hbs[3] 2.0 4.0 hd2[ 1 I ] hbs[ 161 2.0 3.0 hd2[ 1 I ] ha[ 161 2.0 3.0 he1 [ 1 I] hbr[8] 2.0 4.0 hd2[ 1 I ] hbs[ 111 2.0 3.0 he1 [ I 11 hbs[8] 2.0 4.0 hd2[1 I ] hn[12] 2.0 4.0 he1 [ 1 I] hn[8] 2.0 4.0 hd2[1 I ] hn[16] 2.0 4.0 Methyls mg2[17] hn[17] 2.0 4.0 mg2[17] ha[17] 2.0 4.0 Betas hbs[ 1 I] hbr[ 151 2.0 3.0 Tryptophan Aromatics hdl[4] ha[4] 2.0 4.0 he3[4] ha[4] 2.0 4.0 hd1[4] hn[4] 2.0 4.0 he3[4] ha[5] 2.0 4.0

"In this table only, residues (in brackets) are numbered 1-18, beginning with the N-terminal Lys. Numbers for pairs of protons represent lower and upper (- = infinite) distance restraints. Atom definitions: h = single proton; m = methyl; a, b, c, d, and e = alpha, beta, gamma, delta, and epsilon, respectively; r = pro-R and s = pro4 stereochemistry.

Q

0

Q A

0

8)

D

0

ala

0

7!2

ppm

FIGURE 5: (Top) Superposition of the group A' structures onto the group A structures showing backbone atoms only of residues C(I)